Terminal housing, panel of terminal housing, and terminal

ABSTRACT

The terminal housing includes a first panel and a second panel, where a material of the first panel or a material of the second panel is glass. The first panel includes a first main face that is flat and straight and a first side face. The first main face has at least one first vertex angle, the first main face has two margins on two sides of the first vertex angle and connected to the first vertex angle, and cross sections in a through-thickness direction of the first panel and respectively vertical to the two margins connected to the first vertex angle are respectively a first through-thickness cross section and a second through-thickness cross section.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to Chinese Patent Application No.201620419033.4 filed on May 10, 2016, which is hereby incorporated byreference in its entirety.

TECHNICAL FIELD

The present utility model relates to the field of terminal technologies,and in particular, to a terminal housing, a panel of a terminal housing,and a terminal.

BACKGROUND

Currently, housings of some terminals, such as smartphones, on themarket mainly include three parts, a glass touchpad, a middle frame, anda battery rear cover. For this type of terminal housing, there isgenerally a corner angle at a location where faces join. Generally, thecorner angle is located at a location relatively prominent, and is moreprone to be hit by another object compared with other parts of theterminal housing. After being hit, a corner angle location of thehousing is prone to be knocked off or damaged. After the corner angle ofthe housing is knocked off or damaged, appearance of the terminal isaffected, and the corner angle of the housing also fails to protect aninternal part of the terminal. As a result, the internal part of theterminal is prone to be damaged.

SUMMARY

The present utility model provides a terminal housing, a panel of aterminal housing, and a terminal in order to reduce a probability thatthe terminal housing is knocked off or crashed at a location where facesjoin, thereby maintaining a protective effect on an internal part of theterminal.

A first aspect of the present utility model discloses a terminalhousing, including a first panel and a second panel, where the firstpanel and the second panel are respectively snap-fit on front and rearsides of a terminal, the first panel and the second panel are disposedopposite to each other, a material of the first panel and/or a materialof the second panel are/is glass, the first panel includes a first mainface that is flat and straight and a first side face connected to amargin of the first main face, the first main face has at least onefirst vertex angle, the first main face has two margins on two sides ofthe first vertex angle and connected to the first vertex angle, andcross sections in a through-thickness direction of the first panel andthat are respectively vertical to the two margins connected to the firstvertex angle are respectively a first through-thickness cross sectionand a second through-thickness cross section, and a location of the atleast one first vertex angle of the first main face is connected to thefirst side face at a junction of the location of the at least one firstvertex angle and the first side face using a first vertex angle camberedface, inner- and outer-side faces of the first vertex angle camberedface are separately in a shape of a camber line on a firstthrough-thickness cross section that passes through the first vertexangle, and the inner- and outer-side faces of the first vertex anglecambered face are separately in a shape of a camber line on a secondthrough-thickness cross section that passes through the first vertexangle.

In this type of cambered face design of a terminal housing in which alocation of at least one first vertex angle of a first main face isconnected to a first side face at a junction of the location of the atleast one first vertex angle and the first side face using a firstvertex angle cambered face, there is no prominent corner angle such thatthe terminal housing is less prone to be hit by another object. This canreduce a probability that the terminal housing is knocked off or crashedat a location where faces join, thereby maintaining a protective effecton an internal part of a terminal. In addition, this type of cambereddesign, in which dual-curve-line three dimensional (3D) glass is used,of inner- and outer-side faces of the first vertex angle cambered facegreatly enhances an aesthetic appeal of the terminal housing and makesan appearance of the terminal more gentle and flexible.

With reference to the first aspect, in a first possible implementationmanner, the second panel includes a second main face that is flat andstraight and a second side face connected to a margin of the second mainface, the second main face has at least one second vertex angle, thesecond main face has two margins on two sides of the second vertex angleand connected to the second vertex angle, and cross sections in athrough-thickness direction of the second panel and respectivelyvertical to the two margins connected to the second vertex angle arerespectively a third through-thickness cross section and a fourththrough-thickness cross section, and a location of the at least onesecond vertex angle of the second main face is connected to the secondside face at a junction of the location of the at least one secondvertex angle and the second side face using a second vertex anglecambered face, inner- and outer-side faces of the second vertex anglecambered face are separately in a shape of a camber line on a thirdthrough-thickness cross section that passes through the second vertexangle, and the inner- and outer-side faces of the second vertex anglecambered face are separately in a shape of a camber line on a fourththrough-thickness cross section that passes through the second vertexangle.

In this type of cambered face design of a terminal housing in which alocation of at least one second vertex angle of a second main face isconnected to a second side face at a junction of the location of the atleast one second vertex angle and the second side face using a firstvertex angle cambered face, there is no prominent corner angle such thatthe terminal housing is less prone to be hit by another object. This canreduce a probability that the terminal housing is knocked off or crashedat a location where faces join, thereby maintaining a protective effecton an internal part of a terminal.

With reference to the first aspect or the first possible implementationmanner, in a second possible implementation manner, the inner- andouter-side faces of the first vertex angle cambered face are separatelyin a shape of a camber line on each first through-thickness crosssection.

With reference to the first aspect or the first possible implementationmanner, in a third possible implementation manner, the inner- andouter-side faces of the first vertex angle cambered face are separatelyin a shape of a camber line on each second through-thickness crosssection.

With reference to the first aspect or the first possible implementationmanner, in a fourth possible implementation manner, the inner- andouter-side faces of the first vertex angle cambered face are separatelyin a shape of a camber line on each cross section that passes throughthe first vertex angle and in the through-thickness direction of thefirst panel.

With reference to the first aspect or the first possible implementationmanner, in a fifth possible implementation manner, the inner- andouter-side faces of the first vertex angle cambered face are separatelyin a shape of a camber line on each cross section of the first panel andin a direction parallel to the first main face.

With reference to any one of the first aspect or the first to the fifthpossible implementation manners, in a sixth possible implementationmanner, the two margins of the first main face located on the two sidesof the first vertex angle are straight edges or cambered edges.

With reference to any one of the first aspect or the first to the sixthpossible implementation manners, in a seventh possible implementationmanner, the first main face is a rectangle, and there are four firstvertex angles.

With reference to any one of the first aspect or the first to the fifthpossible implementation manners, in an eighth possible implementationmanner, the first main face and the two margins connected to the twosides of the at least one first vertex angle are connected at a junctionof the first main face and the first side face using a cambered face.

With reference to any one of the first aspect or the first to the fifthpossible implementation manners, in a ninth possible implementationmanner, the first side face is a cambered side face or a plate sideface.

With reference to any one of the first aspect or the first to the ninthpossible implementation manners, in a tenth possible implementationmanner, the first side face surrounds a periphery of the first mainface, and is connected to a margin of the periphery of the first mainface.

With reference to any one of the first aspect or the first to the tenthpossible implementation manners, in an eleventh possible implementationmanner, a thickness of the first panel and/or a thickness of the secondpanel are/is even, and inner- and outer-side faces of the first paneland/or inner- and outer-side faces of the second panel are of aconsistent shape.

With reference to any one of the first aspect or the first to theeleventh possible implementation manners, in a twelfth possibleimplementation manner, the terminal housing further includes a middleframe, and the first panel and the second panel are respectivelyassembled on two sides of the middle frame.

Optionally, the first panel and the second panel may be directlyconnected using a medium, for example, liquid glue, solid glue, ordouble-sided tape, or the first panel and the second panel may bedirectly connected in a mechanical manner, for example, connected bymeans of soldering, riveting, screws, or fasteners.

With reference to any one of the first aspect or the first to thetwelfth possible implementation manners, in a thirteenth possibleimplementation manner, the first panel and the second panel aresymmetrical relative to a first cross section located at a centralposition in a through-thickness direction of the terminal. In this way,an overall appearance of the terminal housing can be relativelysymmetrical, improving a visual effect.

With reference to any one of the first aspect or the first to thethirteenth possible implementation manners, in a fourteenth possibleimplementation manner, a shape of an outer surface of the first mainface is any one of an oblong, a trapezoid, a heart shape, a star shape,a regular hexagon, or a boat shape.

With reference to the fourteenth possible implementation manner, in afifteenth possible implementation manner, a shape of the first main faceis a rectangle, the margin of the first main face includes a first widthedge and a second width edge in a width direction of the first main faceand a first length edge and a second length edge in a length directionof the first main face, and at least one edge of the first width edge,the second width edge, the first length edge, and the second length edgeand the first side face are connected at a junction of the at least oneedge and the first side face using a cambered face.

With reference to the fifteenth possible implementation manner, in asixteenth possible implementation manner, the first width edge and thesecond width edge are connected at a junction with the first side faceusing a cambered face, or the first length edge and the second lengthedge are connected at a junction with the first side face using acambered face, or the first width edge, the second width edge, the firstlength edge, and the second length edge are connected at a junction withthe first side face using a cambered face.

With reference to the sixteenth possible implementation manner, in aseventeenth possible implementation manner, a first cambered face isused for connection at a junction of the first width edge and the firstside face, and a second cambered face is used for connection at ajunction of the second width edge and the first side face, where thefirst cambered face and the second cambered face are asymmetricalrelative to a second cross section located at a central position in alength direction of the terminal.

With reference to the sixteenth possible implementation manner, in aneighteenth possible implementation manner, a first cambered face is usedfor connection at a junction of the first width edge and the first sideface, and a second cambered face is used for connection at a junction ofthe second width edge and the first side face, where the first camberedface and the second cambered face are symmetrical relative to a secondcross section located at a central position in a length direction of theterminal.

With reference to the sixteenth possible implementation manner, in anineteenth possible implementation manner, a third cambered face is usedfor connection at a junction of the first length edge and the first sideface, and a fourth cambered face is used for connection at a junction ofthe second length edge and the first side face, where the third camberedface and the fourth cambered face are symmetrical relative to a thirdcross section located at a central position in a width direction of theterminal.

With reference to the sixteenth possible implementation manner, in atwentieth possible implementation manner, a first cambered face is usedfor connection at a junction of the first width edge and the first sideface, a second cambered face is used for connection at a junction of thesecond width edge and the first side face, a third cambered face is usedfor connection at a junction of the first length edge and the first sideface, and a fourth cambered face is used for connection at a junction ofthe second length edge and the first side face, where the first camberedface and the second cambered face are asymmetrical relative to a secondcross section located at a central position in a length direction of theterminal, and the third cambered face and the fourth cambered face aresymmetrical relative to a third cross section located at a centralposition in a width direction of the terminal, or the first camberedface and the second cambered face are symmetrical relative to a secondcross section located at a central position in a length direction of theterminal, and the third cambered face and the fourth cambered face aresymmetrical relative to a third cross section located at a centralposition in a width direction of the terminal.

With reference to any one of the first to the twentieth possibleimplementation manners, in a twenty-first possible implementationmanner, a shape of an outer surface of the second main face is any oneof an oblong, a trapezoid, a heart shape, a star shape, a regularhexagon, or a boat shape.

With reference to the twenty-first possible implementation manner, in atwenty-second possible implementation manner, a shape of the second mainface is a rectangle, the margin of the second main face includes a thirdwidth edge and a fourth width edge in a width direction of the secondmain face and a third length edge and a fourth length edge in a lengthdirection of the second main face, and at least one edge of the thirdwidth edge, the fourth width edge, the third length edge, and the fourthlength edge and the second side face are connected at a junction of theat least one edge and the second side face using a cambered face.

With reference to the twenty-second possible implementation manner, in atwenty-third possible implementation manner, the third width edge andthe fourth width edge are connected at a junction with the second sideface using a cambered face, or the third length edge and the fourthlength edge are connected at a junction with the second side face usinga cambered face, or the third width edge, the fourth width edge, thethird length edge, and the fourth length edge are connected at ajunction with the second side face using a cambered face.

With reference to the twenty-third possible implementation manner, in atwenty-fourth possible implementation manner, a fifth cambered face isused for connection at a junction of the third width edge and the secondside face, and a sixth cambered face is used for connection at ajunction of the fourth width edge and the second side face, where thefifth cambered face and the sixth cambered face are asymmetricalrelative to the second cross section located at the central position inthe length direction of the terminal.

With reference to the twenty-third possible implementation manner, in atwenty-fifth possible implementation manner, a fifth cambered face isused for connection at a junction of the third width edge and the secondside face, and a sixth cambered face is used for connection at ajunction of the fourth width edge and the second side face, where thefifth cambered face and the sixth cambered face are symmetrical relativeto the second cross section located at the central position in thelength direction of the terminal.

With reference to the twenty-third possible implementation manner, in atwenty-sixth possible implementation manner, a seventh cambered face isused for connection at a junction of the third length edge and thesecond side face, and an eighth cambered face is used for connection ata junction of the fourth length edge and the second side face, where theseventh cambered face and the eighth cambered face are symmetricalrelative to the third cross section located at the central position inthe width direction of the terminal.

With reference to the twenty-third possible implementation manner, in atwenty-seventh possible implementation manner, a fifth cambered face isused for connection at a junction of the third width edge and the secondside face, a sixth cambered face is used for connection at a junction ofthe fourth width edge and the second side face, a seventh cambered faceis used for connection at a junction of the third length edge and thesecond side face, and an eighth cambered face is used for connection ata junction of the fourth length edge and the second side face, where thefifth cambered face and the sixth cambered face are asymmetricalrelative to the second cross section located at the central position inthe length direction of the terminal, and the seventh cambered face andthe eighth cambered face are symmetrical relative to the third crosssection located at the central position in the width direction of theterminal, or the fifth cambered face and the sixth cambered face aresymmetrical relative to the second cross section located at the centralposition in the length direction of the terminal, and the seventhcambered face and the eighth cambered face are symmetrical relative tothe third cross section located at the central position in the widthdirection of the terminal.

With reference to any one of the first aspect or the first to thetwenty-seventh possible implementation manners of the first aspect, in atwenty-eighth possible implementation manner, the first panel and/or thesecond panel are/is display screens/a display screen.

With reference to any one of the first aspect or the first to thetwenty-eighth possible implementation manners of the first aspect, in atwenty-ninth possible implementation manner, an overall form of thefirst panel or the second panel is any one of an oblong body with acambered edge, a trapezoid body with a cambered edge, a heart-shapedbody with a cambered edge, a star-shaped body with a cambered edge, aregular hexagon body with a cambered edge, or a boat-shaped body with acambered edge.

A second aspect of the present utility model discloses a panel of aterminal housing, where the panel is configured to be snap-fit on afront side or a rear side of a terminal, a material of the panel isglass, the panel includes a first main face that is flat and straightand a first side face connected to a margin of the first main face, thefirst main face has at least one vertex angle, the first main face hastwo margins on two sides of the vertex angle and connected to the vertexangle, and cross sections in a through-thickness direction of the firstpanel and that are respectively vertical to the two margins connected tothe vertex angle are respectively a first through-thickness crosssection and a second through-thickness cross section, and a location ofthe at least one vertex angle of the first main face is connected to thefirst side face at a junction of the location of the at least one vertexangle and the first side face using a vertex angle cambered face, inner-and outer-side faces of the vertex angle cambered face are separately ina shape of a camber line on a first through-vertex-angle cross sectionthat passes through the vertex angle, and the inner- and outer-sidefaces of the vertex angle cambered face are separately in a shape of acamber line on a second through-vertex-angle cross section that passesthrough the vertex angle.

With reference to the second aspect, in a first possible implementationmanner, the inner- and outer-side faces of the vertex angle camberedface are separately in a shape of a camber line on each firstthrough-thickness cross section.

With reference to the second aspect, in a second possible implementationmanner, the inner- and outer-side faces of the vertex angle camberedface are separately in a shape of a camber line on each secondthrough-thickness cross section.

With reference to the second aspect, in a third possible implementationmanner, the inner- and outer-side faces of the vertex angle camberedface are separately in a shape of a camber line on each cross sectionthat passes through the vertex angle in the through-thickness directionof the panel.

With reference to the second aspect, in a fourth possible implementationmanner, the inner- and outer-side faces of the vertex angle camberedface are separately in a shape of a camber line on each cross section ofthe panel in a direction parallel to the first main face.

With reference to any one of the second aspect or the first to thefourth possible implementation manners, in a fifth possibleimplementation manner, the two margins of the first main face located onthe two sides of the vertex angle are straight edges or cambered edges.

With reference to any one of the second aspect or the first to the fifthpossible implementation manners, in a sixth possible implementationmanner, the first main face is a rectangle, and there are four firstvertex angles.

With reference to any one of the second aspect or the first to thefourth possible implementation manners, in a seventh possibleimplementation manner, the first main face and the two margins connectedto the two sides of the at least one vertex angle are connected to thefirst side face at a junction of the first main face and the first sideface using a cambered face.

With reference to any one of the second aspect or the first to thefourth possible implementation manners, in an eighth possibleimplementation manner, the first side face is a cambered side face or aplate side face.

With reference to any one of the second aspect or the first to theeighth possible implementation manners, in a ninth possibleimplementation manner, the first side face surrounds a periphery of thefirst main face, and is connected to a margin of the periphery of thefirst main face.

With reference to any one of the second aspect or the first to the ninthpossible implementation manners, in a tenth possible implementationmanner, a thickness of the panel is even, and inner- and outer-sidefaces of the panel are of a consistent shape.

A third aspect of the present utility model discloses a terminal,including the terminal housing according to any of the first aspect, acircuit board disposed in the terminal housing, and a part disposed onthe circuit board, where a panel of the terminal housing includes thepanel according to any of the second aspect.

In a possible implementation manner, the inner- and outer-side faces ofthe second vertex angle cambered face are separately in a shape of acamber line on each third through-thickness cross section.

In a possible implementation manner, the inner- and outer-side faces ofthe second vertex angle cambered face are separately in a shape of acamber line on each fourth through-thickness cross section.

In a possible implementation manner, the inner- and outer-side faces ofthe second vertex angle cambered face are separately in a shape of acamber line on each cross section that passes through the vertex anglein the through-thickness direction of the second panel.

In a possible implementation manner, the inner- and outer-side faces ofthe second vertex angle cambered face are separately in a shape of acamber line on each cross section of the second panel in a directionparallel to the second main face.

In a possible implementation manner, the two margins of the second mainface located on the two sides of the second vertex angle are straightedges or cambered edges.

In a possible implementation manner, the second main face is arectangle, and there are four second vertex angles.

In a possible implementation manner, the second main face and the twomargins connected to the two sides of the at least one second vertexangle are connected at a junction of the second main face and the secondside face using a cambered face.

In a possible implementation manner, the second side face is a camberedside face or a plate side face.

In a possible implementation manner, the second side face surrounds aperiphery of the second main face, and is connected to a margin of theperiphery of the second main face.

In a possible implementation manner, at least one of a visible-lightcamera, an infrared camera, an ambient-light sensor, or an infraredlight emitting diode (LED) is disposed on the first panel. At least oneof a visible-light camera, a camera flash, or a laser sensor is disposedon the second panel. Using this design approach, a richer appearance ofthe terminal housing is achieved, and design innovation in appearancedetails is not restricted.

In a possible implementation manner, a third cambered face is used forconnection at a junction of the first length edge and the first sideface, and a fourth cambered face is used for connection at a junction ofthe second length edge and the first side face, where the third camberedface and the fourth cambered face are asymmetrical relative to a thirdcross section located at the central position in the width direction ofthe terminal.

In a possible implementation manner, a seventh cambered face is used forconnection at a junction of the third length edge and the second sideface, and an eighth cambered face is used for connection at a junctionof the fourth length edge and the second side face, where the seventhcambered face and the eighth cambered face are asymmetrical relative tothe third cross section located at the central position in the widthdirection of the terminal.

It can be learned that, in the embodiments of the present utility model,in this type of cambered face design of a terminal housing in which alocation of at least one first vertex angle of a first main face isconnected to a first side face at a junction of the location of the atleast one first vertex angle and the first side face using a firstvertex angle cambered face, there is no prominent corner angle such thatthe terminal housing is less prone to be hit by another object. This canreduce a probability that the terminal housing is knocked off or crashedat a location where faces join, thereby maintaining a protective effecton an internal part of a terminal.

BRIEF DESCRIPTION OF DRAWINGS

To describe the technical solutions in the embodiments of the presentutility model more clearly, the following briefly describes theaccompanying drawings required for describing the embodiments. Theaccompanying drawings in the following description show merely someembodiments of the present utility model, and a person of ordinary skillin the art may still derive other drawings from these accompanyingdrawings without creative efforts.

FIG. 1 is a schematic front view of a first panel disclosed in anembodiment of the present utility model;

FIG. 2A is a 3D schematic structural diagram of a first panel disclosedin an embodiment of the present utility model;

FIG. 2B is a schematic side view of a first panel disclosed in anembodiment of the present utility model;

FIG. 2C is another schematic side view of a first panel disclosed in anembodiment of the present utility model;

FIG. 2D is another schematic side view of a first panel disclosed in anembodiment of the present utility model;

FIG. 3 is a schematic front view of a second panel disclosed in anembodiment of the present utility model;

FIG. 4A is a 3D schematic structural diagram of a second panel disclosedin an embodiment of the present utility model;

FIG. 4B is a schematic side view of a second panel disclosed in anembodiment of the present utility model;

FIG. 4C is another schematic side view of a second panel disclosed in anembodiment of the present utility model;

FIG. 4D is another schematic side view of a second panel disclosed in anembodiment of the present utility model;

FIG. 5A is a schematic sectional view of a first implementation mannerof a terminal housing disclosed in an embodiment of the present utilitymodel;

FIG. 5B is another schematic sectional view of a first implementationmanner of a terminal housing disclosed in an embodiment of the presentutility model;

FIG. 6A is a schematic sectional view of a second implementation mannerof a terminal housing disclosed in an embodiment of the present utilitymodel; and

FIG. 6B is another schematic sectional view of a second implementationmanner of a terminal housing disclosed in an embodiment of the presentutility model.

DESCRIPTION OF EMBODIMENTS

The following clearly describes the technical solutions in theembodiments of the present utility model with reference to theaccompanying drawings in the embodiments of the present utility model.The described embodiments are merely some but not all of the embodimentsof the present utility model. All other embodiments obtained by a personof ordinary skill in the art based on the embodiments of the presentutility model without creative efforts shall fall within the protectionscope of the present utility model.

An “embodiment” mentioned in this application means that a specificfeature, structure, or attribute described with reference to theembodiment may be included in at least one embodiment of the presentutility model. The phrase occurred at different locations in thespecification does not necessarily refer to a same embodiment, or anindependent or alternative embodiment exclusive of another embodiment. Aperson skilled in the art understands, in explicit and implicit manners,that an embodiment described in this application may be combined withanother embodiment.

Embodiments of the present utility model disclose a terminal housing, apanel of a terminal housing, and a terminal in order to reduce aprobability that the terminal housing is knocked off or crashed at alocation where faces join, thereby maintaining a protective effect on aninternal part of the terminal. Detailed descriptions are separatelyprovided in the following

The terminal includes the terminal housing, a circuit board disposed inthe terminal housing, and a part disposed on the circuit board. Theterminal housing is configured to protect the internal part of theterminal, to prevent the internal part of the terminal from beingdamaged. The terminal may include but is not limited to different typesof smart terminals such as a smartphone, a notebook computer, a personalcomputer (PC), a personal digital assistant (PDA), a mobile Internetdevice (MID), or a smart wearable device, such as a smart watch or asmart band. In the embodiments of the present utility model, theterminal housing being applied in a smartphone is used as an example.

The terminal housing includes a first panel and a second panel. Thefirst panel and the second panel are respectively snap-fit on front andrear sides of the terminal, and the first panel and the second panel aredisposed opposite to each other. That “the first panel and the secondpanel are respectively snap-fit on front and rear sides of the terminal”may be understood as “the first panel is snap-fit on the front side ofthe terminal, and the second panel is snap-fit on the rear side of theterminal”, or that “the first panel and the second panel arerespectively snap-fit on front and rear sides of the terminal” may beunderstood as “the first panel is snap-fit on the rear side of theterminal, and the second panel is snap-fit on the front side of theterminal.” This embodiment of the present utility model sets nolimitation thereto.

A material of the first panel and/or a material of the second panelare/is glass. The term “and/or” herein may be understood that threecases exist. The material of the first panel is glass, or the materialof the second panel is glass, or both the material of the first paneland the material of the second panel are glass. All the glass herein is3D glass. Both upper and lower surfaces of the 3D glass have a featureof a cambered face.

An overall form of the first panel or the second panel is any one of anoblong body with a cambered edge, a trapezoid body with a cambered edge,a heart-shaped body with a cambered edge, a star-shaped body with acambered edge, a regular hexagon body with a cambered edge, or aboat-shaped body with a cambered edge. The first panel and the secondpanel are symmetrical relative to a first cross section located at acentral position in a through-thickness direction of the terminal.

A thickness of the first panel and/or a thickness of the second panelare/is even, and inner- and outer-side faces of the first panel and/orinner- and outer-side faces of the second panel are of a consistentshape. The term “and/or” may be understood that three cases exist. Thethickness of the first panel is even, and the inner- and outer-sidefaces of the first panel are of a consistent shape, or the thickness ofthe second panel is even, and the inner- and outer-side faces of thesecond panel are of a consistent shape, or the thickness of the firstpanel and the thickness of the second panel are even, and the inner- andouter-side faces of the first panel and the inner- and outer-side facesof the second panel are of a consistent shape.

The first panel and/or the second panel are/is display screens/a displayscreen. The term “and/or” may be understood that three cases exist. Thefirst panel is a display screen, and in this case, the second panel maybe a battery cover, or the second panel is a display screen, and in thiscase, the first panel may be a battery cover, or both the first paneland the second panel are display screens.

The first panel includes a first main face that is flat and straight anda first side face connected to a margin of the first main face, thefirst main face has at least one first vertex angle, the first main facehas two margins on two sides of the first vertex angle connected to thefirst vertex angle, and cross sections in a through-thickness directionof the first panel and respectively vertical to the two marginsconnected to the first vertex angle are respectively a firstthrough-thickness cross section and a second through-thickness crosssection. The first vertex angle may be a sharp corner or may be achamfer. This is not limited in this embodiment of the present utilitymodel. Optionally, a shape of an outer surface of the first main face isany one of an oblong, a trapezoid, a heart shape, a star shape, aregular hexagon, or a boat shape.

A location of the at least one first vertex angle of the first main faceis connected to the first side face at a junction of the location of theat least one first vertex angle and the first side face using a firstvertex angle cambered face, inner- and outer-side faces of the firstvertex angle cambered face are separately in a shape of a camber line ona first through-thickness cross section that passes through the firstvertex angle, and the inner- and outer-side faces of the first vertexangle cambered face are separately in a shape of a camber line on asecond through-thickness cross section that passes through the firstvertex angle. It can be learned that, in this type of design, in whichdual-cambered-face 3D glass is used, of the first panel, there is noprominent corner angle such that the first panel is less prone to be hitby another object. This can reduce a probability that the terminalhousing is knocked off or crashed at a location where faces join,thereby maintaining a protective effect on an internal part of theterminal.

In addition, in terms of detail design, at least one of a visible-lightcamera, an infrared camera, an ambient-light sensor, or an infrared LEDmay be further disposed on the first panel. Decoration of the firstpanel using printing ink may be performed in multiple manners, forexample, by means of screen printing, coating, or movable printing, or apiece of membrane may be attached to the first panel. In this type ofdetail design manner of the first panel, a richer appearance isachieved, and design innovation in appearance details is not restricted.

The second panel includes a second main face that is flat and straightand a second side face connected to a margin of the second main face,the second main face has at least one second vertex angle, the secondmain face has two margins on two sides of the second vertex angleconnected to the second vertex angle, and cross sections in athrough-thickness direction of the second panel respectively vertical tothe two margins connected to the second vertex angle are respectively athird through-thickness cross section and a fourth through-thicknesscross section. The second vertex angle may be a sharp corner or may be achamfer. This is not limited in this embodiment of the present utilitymodel. Optionally, a shape of an outer surface of the second main faceis any one of an oblong, a trapezoid, a heart shape, a star shape, aregular hexagon, or a boat shape.

A location of the at least one second vertex angle of the second mainface is connected to the second side face at a junction of the locationof the at least one second vertex angle and the second side face using asecond vertex angle cambered face, inner- and outer-side faces of thesecond vertex angle cambered face are separately in a shape of a camberline on a third through-thickness cross section that passes through thesecond vertex angle, and the inner- and outer-side faces of the secondvertex angle cambered face are separately in a shape of a camber line ona fourth through-thickness cross section that passes through the secondvertex angle. It can be learned that, in this type of design, in whichdual-cambered-face 3D glass is used, of the second panel, there is noprominent corner angle such that the second panel is less prone to behit by another object. This can reduce a probability that the terminalhousing is knocked off or crashed at a location where faces join,thereby maintaining a protective effect on an internal part of theterminal.

In addition, in terms of detail design, at least one of a visible-lightcamera, a camera flash, or a laser sensor may be further disposed on thesecond panel. Decoration of the second panel using printing ink may beperformed in multiple manners, for example, by means of screen printing,coating, or movable printing, or a piece of membrane may be attached tothe second panel. In this type of detail design manner of the secondpanel, a richer appearance is achieved, and design innovation inappearance details is not restricted.

An overall form of the first panel may assume a shape of a plate, or agroove is disposed on an inner side of the first panel, where the grooveholds an internal part of the terminal. An overall form of the secondpanel may assume a shape of a plate, or a groove is disposed on an innerside of the second panel, where the groove holds an internal part of theterminal.

Based on the foregoing descriptions of the overall forms of the firstpanel and the second panel, an overall structural form of the terminalhousing mainly includes the following several types.

In a first type, the overall form of the first panel assumes a shape ofa plate, and a groove is disposed on the inner side of the second panel,where the groove holds an internal part of the terminal.

In a second type, the overall form of the second panel assumes a shapeof a plate, and a groove is disposed on the inner side of the firstpanel, where the groove holds an internal part of the terminal.

In a third type, a groove is disposed on the inner sides of both thefirst panel and the second panel, where the groove holds an internalpart of the terminal.

Optionally, in the foregoing several combination manners, the terminalhousing further includes a middle frame. The first panel and the secondpanel are respectively assembled on two sides of the middle frame. Themiddle frame may be prepared using metal, alloy, a polymer material, andvarious types of composite materials. A buffer material, such as foam,rubber, or plastic or a component may be used for buffering between themiddle frame and the first panel and between the middle frame and thesecond panel.

Optionally, in the foregoing several combination manners, the firstpanel and the second panel may be directly connected using a medium, forexample, liquid glue, solid glue, or double-sided tape, or the firstpanel and the second panel may be directly connected in a mechanicalmanner, for example, connected by means of soldering, riveting, screws,or fasteners.

The following first separately describes the cambered face design of thefirst panel and the second panel in the present utility model.

Refer to FIG. 1 to FIG. 2D. FIG. 1 is a schematic front view of a firstpanel disclosed in an embodiment of the present utility model. FIG. 2Ais a 3D schematic structural diagram of a first panel disclosed in anembodiment of the present utility model. FIG. 2B is a schematic sideview of a first panel disclosed in an embodiment of the present utilitymodel. FIG. 2C is another schematic side view of a first panel disclosedin an embodiment of the present utility model. FIG. 2D is anotherschematic side view of a first panel disclosed in an embodiment of thepresent utility model. An overall form of the first panel is an oblongbody with a cambered edge, and a shape of the first main face is arectangle.

As shown in FIG. 1 and FIG. 2A, the first panel 1 includes a first mainface 11 that is flat and straight and a first side face 12 connected toa margin of the first main face 11, the first main face 11 has at leastone first vertex angle 17, the first main face 11 has two margins on twosides of the first vertex angle 17 and connected to the first vertexangle 17, and cross sections in a through-thickness direction of thefirst panel 1 respectively vertical to the two margins connected to thefirst vertex angle 17 are respectively a first through-thickness crosssection (as shown in FIG. 2B and FIG. 2C) and a second through-thicknesscross section (as shown in FIG. 2D).

A location of the at least one first vertex angle 17 of the first mainface 11 is connected to the first side face 12 at a junction of thelocation of the at least one first vertex angle 17 and the first sideface 12 using a first vertex angle cambered face 13 (as shown in FIG. 2Bor FIG. 2C), inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on a firstthrough-thickness cross section that passes through the first vertexangle 17, and the inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on a secondthrough-thickness cross section that passes through the first vertexangle 17.

Optionally, the inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on eachfirst through-thickness cross section.

Optionally, the inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on eachsecond through-thickness cross section.

Optionally, the inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on eachcross section that passes through the first vertex angle 17 in thethrough-thickness direction of the first panel 1.

Optionally, the inner- and outer-side faces of the first vertex anglecambered face 13 are separately in a shape of a camber line on eachcross section of the first panel 1 and in a direction parallel to thefirst main face 11.

Optionally, the two margins of the first main face 11 located on the twosides of the first vertex angle 17 are straight edges or cambered edges.

Optionally, the first main face 11 is a rectangle, and there are fourfirst vertex angles 17.

Optionally, the first main face 11 and the two margins connected to thetwo sides of the at least one first vertex angle 17 are connected at ajunction of the first main face 11 and the first side face 12 using acambered face.

Optionally, the first side face 12 is a cambered side face or a plateside face.

Optionally, the first side face 12 surrounds a periphery of the firstmain face 11, and is connected to a margin of the periphery of the firstmain face 11.

As shown in FIG. 1 or FIG. 2A, the margin of the first main face 11includes a first width edge 111 and a second width edge 112 in a widthdirection of the first main face 11 and a first length edge 113 and asecond length edge 114 in a length direction of the first main face 11,and at least one edge of the first width edge 111, the second width edge112, the first length edge 113, and the second length edge 114 and thefirst side face 12 are connected at a junction of the at least one edgeand the first side face 12 using a cambered face. This type ofcambered-face design of the first panel 1 may greatly enhance anaesthetic appeal of a terminal housing and make an appearance of aterminal more gentle and flexible.

As shown in FIG. 2B, a first cambered face 13 is used for connection ata junction of the first width edge 111 and the first side face 12, and asecond cambered face 14 is used for connection at a junction of thesecond width edge 112 and the first side face 12. The first camberedface 13 and the second cambered face 14 are asymmetrical relative to asecond cross section located at a central position in a length directionof the terminal. That is, degrees of curvature of the first camberedface 13 and the second cambered face 14 are different. Generally, adegree of curvature of a cambered face may be described using acurvature parameter, such as a radian, inclination, curvature, or acurvature radius. A corresponding degree of curvature of a cambered facevaries according to a curvature parameter.

Optionally, as shown in FIG. 2C, the first cambered face 13 and thesecond cambered face 14 are symmetrical relative to a second crosssection located at a central position in a length direction of theterminal.

As shown in FIG. 2D, a third cambered face 15 is used for connection ata junction of the first length edge 113 and the first side face 12, anda fourth cambered face 16 is used for connection at a junction of thesecond length edge 114 and the first side face 12, where the thirdcambered face 15 and the fourth cambered face 16 are symmetricalrelative to a third cross section located at a central position in awidth direction of the terminal. In addition, optionally, the thirdcambered face 15 and the fourth cambered face 16 are asymmetricalrelative to a third cross section located at the central position in thewidth direction of the terminal and this is not illustrated.

It can be learned that, in this type of cambered face design of aterminal housing in which a location of at least one first vertex angleof a first main face is connected to a first side face at a junction ofthe location of the at least one first vertex angle and the first sideface using a first vertex angle cambered face, there is no prominentcorner angle such that the terminal housing is less prone to be hit byanother object. This can reduce a probability that the terminal housingis knocked off or crashed at a location where faces join, therebymaintaining a protective effect on an internal part of a terminal. Inaddition, this type of cambered design, in which dual-curve-line 3Dglass is used, of inner- and outer-side faces of the first vertex anglecambered face greatly enhances an aesthetic appeal of the terminalhousing and makes an appearance of the terminal more gentle andflexible.

Refer to FIG. 3 to FIG. 4D. FIG. 3 is a schematic front view of a secondpanel disclosed in an embodiment of the present utility model. FIG. 4Ais a 3D schematic structural diagram of a second panel disclosed in anembodiment of the present utility model. FIG. 4B is a schematic sideview of a second panel disclosed in an embodiment of the present utilitymodel. FIG. 4C is another schematic side view of a second paneldisclosed in an embodiment of the present utility model. FIG. 4D isanother schematic side view of a second panel disclosed in an embodimentof the present utility model. An overall form of the second panel is anoblong body with a cambered edge, and a shape of the second main face isa rectangle.

As shown in FIG. 3 and FIG. 4A, the second panel 2 includes a secondmain face 21 that is flat and straight and a second side face 22connected to a margin of the second main face 21, the second main face21 has at least one second vertex angle 27, the second main face 21 hastwo margins on two sides of the second vertex angle 27 and connected tothe second vertex angle 27, and cross sections in a through-thicknessdirection of the second panel 2 and respectively vertical to the twomargins connected to the second vertex angle 27 are respectively a thirdthrough-thickness cross section (as shown in FIG. 4B and FIG. 4C) and afourth through-thickness cross section (as shown in FIG. 4D).

A location of the at least one second vertex angle 27 of the second mainface 21 is connected to the second side face 22 at a junction of thelocation of the at least one second vertex angle 27 and the second sideface 22 using a second vertex angle cambered face 23 (as shown in FIG.4B or FIG. 4C), inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on a thirdthrough-thickness cross section that passes through the second vertexangle 27, and the inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on a fourththrough-thickness cross section that passes through the second vertexangle 27.

Optionally, the inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on eachthird through-thickness cross section.

Optionally, the inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on eachfourth through-thickness cross section.

Optionally, the inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on eachcross section that passes through the second vertex angle 27 in thethrough-thickness direction of the second panel 2.

Optionally, the inner- and outer-side faces of the second vertex anglecambered face 23 are separately in a shape of a camber line on eachcross section of the second panel 2 in a direction parallel to thesecond main face 21.

Optionally, the two margins of the second main face 21 located on thetwo sides of the second vertex angle 27 are straight edges or camberededges.

Optionally, the second main face 21 is a rectangle, and there are foursecond vertex angles 27.

Optionally, the second main face 21 and the two margins connected to thetwo sides of the at least one second vertex angle 27 are connected at ajunction of the second main face 21 and the second side face 22 using acambered face.

Optionally, the second side face 22 is a cambered side face or a plateside face.

Optionally, the second side face 22 surrounds a periphery of the secondmain face 21, and is connected to a margin of the periphery of thesecond main face 21.

As shown in FIG. 3 or FIG. 4A, the margin of the second main face 21includes a third width edge 211 and a fourth width edge 212 in a widthdirection of the second main face 21 and a third length edge 213 and afourth length edge 214 in a length direction of the second main face 21,and at least one edge of the third width edge 211, the fourth width edge212, the third length edge 213, and the fourth length edge 214 and thesecond side face 22 are connected at a junction of the at least one edgeand the second side face 22 using a cambered face. This type ofcambered-face design of the second panel 2 may greatly enhance anaesthetic appeal of a terminal housing and make an appearance of aterminal more gentle and flexible.

As shown in FIG. 4B, a fifth cambered face 23 is used for connection ata junction of the third width edge 211 and the second side face 22, anda sixth cambered face 24 is used for connection at a junction of thefourth width edge 212 and the second side face 22. The fifth camberedface 23 and the sixth cambered face 24 are asymmetrical relative to thesecond cross section located at the central position in the lengthdirection of the terminal. That is, degrees of curvature of the fifthcambered face 23 and the sixth cambered face 24 are different.Generally, a degree of curvature of a cambered face may be describedusing a curvature parameter, such as a radian, inclination, curvature,or a curvature radius. A corresponding degree of curvature of a camberedface varies according to a curvature parameter.

Optionally, as shown in FIG. 4C, the fifth cambered face 23 and thesixth cambered face 24 are symmetrical relative to the second crosssection located at the central position in the length direction of theterminal.

As shown in FIG. 4D, a seventh cambered face 25 is used for connectionat a junction of the third length edge 213 and the second side face 22,and an eighth cambered face 26 is used for connection at a junction ofthe fourth length edge 214 and the second side face 22, where theseventh cambered face 25 and the eighth cambered face 26 are symmetricalrelative to the third cross section located at the central position inthe width direction of the terminal. In addition, optionally, theseventh cambered face 25 and the eighth cambered face 26 areasymmetrical relative to the third cross section located at the centralposition in the width direction of the terminal, and this is notillustrated.

It can be learned that, in this type of cambered face design of aterminal housing in which a location of at least one second vertex angle27 of a second main face 21 is connected to a second side face 22 at ajunction of the location of the at least one second vertex angle 27 andthe second side face 22 using a second vertex angle 27 cambered face,there is no prominent corner angle, and the terminal housing is lessprone to be hit by another object. This can reduce a probability thatthe terminal housing is knocked off or crashed at a location where facesjoin, thereby maintaining a protective effect on an internal part of aterminal. In addition, this type of cambered design, in whichdual-curve-line 3D glass is used, of inner- and outer-side faces of thesecond vertex angle 27 cambered face greatly enhances an aestheticappeal of the terminal housing and makes an appearance of the terminalmore gentle and flexible.

Based on the foregoing descriptions of the cambered-face design of thefirst panel and the second panel, the following describes severalcambered-face design manners of a terminal housing.

Refer to FIG. 5A and FIG. 5B. FIG. 5A is a schematic sectional view of afirst implementation manner of a terminal housing disclosed in anembodiment of the present utility model. FIG. 5B is another schematicsectional view of a first implementation manner of a terminal housingdisclosed in an embodiment of the present utility model. A cross sectionshown in FIG. 5A is a cross section located at the central position inthe width direction of the terminal, that is, the third cross section. Across section shown in FIG. 5B is a cross section located at the centralposition in the length direction of the terminal, that is, the secondcross section.

As shown in FIG. 5A and FIG. 5B, a cambered face of the first panel 1and a cambered face of the second panel 2 both use symmetrical design.Further, the first cambered face 13 and the second cambered face 14 aresymmetrical relative to the second cross section located at the centralposition in the length direction of the terminal, the fifth camberedface 23 and the sixth cambered face 24 are symmetrical relative to thesecond cross section located at the central position in the lengthdirection of the terminal, the third cambered face 15 and the fourthcambered face 16 are symmetrical relative to the third cross sectionlocated at the central position in the width direction of the terminal,and the seventh cambered face 25 and the eighth cambered face 26 aresymmetrical relative to the third cross section located at the centralposition in the width direction of the terminal. Generally, a degree ofcurvature of a cambered face may be described using a curvatureparameter, such as a radian, inclination, curvature, or a curvatureradius. A corresponding degree of curvature of a cambered face variesaccording to a curvature parameter. That is, a curvature parameter ofthe first cambered face 13 and a curvature parameter of the secondcambered face 14 are the same, a curvature parameter of the fifthcambered face 23 and a curvature parameter of the sixth cambered face 24are the same, a curvature parameter of the third cambered face 15 and acurvature parameter of the fourth cambered face 16 are the same, and acurvature parameter of the seventh cambered face 25 and a curvatureparameter of the eighth cambered face 26 are the same.

In this embodiment of the present utility model, both the first mainface and the second main face assume a shape of a rectangle. Both amaterial of the first panel 1 and a material of the second panel 2 areglass. Both the first panel 1 and the second panel 2 use design in whichdual-cambered-face 3D glass is used. In this way, there is no prominentcorner angle on a terminal housing such that the terminal housing isless prone to be hit by another object. This can reduce a probabilitythat the terminal housing is knocked off or crashed at a location wherefaces join, thereby maintaining a protective effect on an internal partof a terminal. In addition, the cambered face of the first panel 1 andthe cambered face of the second panel 2 use symmetrical design. Thisgreatly enhances an aesthetic appeal of symmetry of the terminal housingand makes an appearance of the terminal more gentle and flexible.

Refer to FIG. 6A and FIG. 6B. FIG. 6A is a schematic sectional view of asecond implementation manner of a terminal housing disclosed in anembodiment of the present utility model. FIG. 6B is another schematicsectional view of a second implementation manner of a terminal housingdisclosed in an embodiment of the present utility model. A cross sectionshown in FIG. 6A is a cross section located at the central position inthe width direction of the terminal, that is, the third cross section. Across section shown in FIG. 6B is a cross section located at the centralposition in the length direction of the terminal, that is, the secondcross section.

As shown in FIG. 6A and FIG. 6B, a part of a cambered face of the firstpanel 1 and a part of a cambered face of the second panel 2 both useasymmetrical design. Further, the first cambered face 13 and the secondcambered face 14 are asymmetrical relative to the second cross sectionlocated at the central position in the length direction of the terminal,the fifth cambered face 23 and the sixth cambered face 24 areasymmetrical relative to the second cross section located at the centralposition in the length direction of the terminal, the third camberedface 15 and the fourth cambered face 16 are symmetrical relative to thethird cross section located at the central position in the widthdirection of the terminal, and the seventh cambered face 25 and theeighth cambered face 26 are symmetrical relative to the third crosssection located at the central position in the width direction of theterminal. Generally, a degree of curvature of a cambered face may bedescribed using a curvature parameter, such as a radian, inclination,curvature, or a curvature radius. A corresponding degree of curvature ofa cambered face varies according to a curvature parameter. That is, acurvature parameter of the first cambered face 13 and a curvatureparameter of the second cambered face 14 are different, a curvatureparameter of the fifth cambered face 23 and a curvature parameter of thesixth cambered face 24 are different, a curvature parameter of the thirdcambered face 15 and a curvature parameter of the fourth cambered face16 are the same, and a curvature parameter of the seventh cambered face25 and a curvature parameter of the eighth cambered face 26 are thesame.

In this embodiment of the present utility model, both the first mainface and the second main face assume a shape of a rectangle. Both amaterial of the first panel 1 and a material of the second panel 2 areglass. Both the first panel 1 and the second panel 2 use design in whichdual-cambered-face 3D glass is used. In this way, there is no prominentcorner angle on a terminal housing such that the terminal housing isless prone to be hit by another object. This can reduce a probabilitythat the terminal housing is knocked off or crashed at a location wherefaces join, thereby maintaining a protective effect on an internal partof a terminal. In addition, a cambered face of the first panel 1 and acambered face of the second panel 2 use asymmetrical design such that anappearance of the terminal housing has a characteristic ofparticularity. This meets a personalized requirement of a user,improving user experience.

What are disclosed above are merely examples of embodiments of thepresent disclosure, and certainly are not intended to limit theprotection scope of the present disclosure. Any equivalent modificationmade in accordance with the claims of the present disclosure shall fallwithin the scope of the present disclosure.

What is claimed is:
 1. A terminal housing. comprising: a first panel;and a second panel, the first panel and the second panel beingrespectively snap-fit on front and rear sides of a terminal, the firstpanel and the second panel being disposed opposite to each other, amaterial of the first panel or a material of the second panel beingglass, the first panel comprising a first main face that is flat andstraight, and a first side face coupled to a margin of the first mainface, the first main face comprising at least one first vertex angle,two margins on two sides of the at least one first vertex angle andcoupled to the at least one first vertex angle, and cross sections in athrough-thickness direction of the first panel respectively vertical tothe two margins coupled to the at least one first vertex angle arerespectively a first through-thickness cross section and a secondthrough-thickness cross section, a location of the at least one firstvertex angle of the first main face being coupled to the first side faceat a junction of the location of the at least one first vertex angle andthe first side face using a first vertex angle cambered face, inner-sideand outer-side faces of the first vertex angle cambered face areseparately in a shape of a camber line on the first through-thicknesscross section that passes through the at least one first vertex angle,the inner-side and the outer-side faces of the first vertex anglecambered face being separately in a shape of a camber line on the secondthrough-thickness cross section that passes through the at least onefirst vertex angle, the second panel comprising a second main face thatis flat and straight and a second side face coupled to a margin of thesecond main face, the second main face comprising at least one secondvertex angle, two margins on two sides of the at least one second vertexangle and coupled to the at least one second vertex angle, and crosssections in a through-thickness direction of the second panelrespectively vertical to the two margins coupled to the at least onesecond vertex angle are respectively a third through-thickness crosssection and a fourth through-thickness cross section, a location of theat least one second vertex angle of the second main face being coupledto the second side face at a junction of the location of the at leastone second vertex angle and the second side face using a second vertexangle cambered face, inner-side and outer-side faces of the secondvertex angle cambered face being separately in a shape of a camber lineon the third through-thickness cross section that passes through the atleast one second vertex angle, and the inner-side and the outer-sidefaces of the at least one second vertex angle cambered face beingseparately in a shape of a camber line on the fourth through-thicknesscross section that passes through the at least one second vertex angle,a shape of the first main face being a rectangle, the margin of thefirst main face comprising a first width edge and a second width edge ina width direction of the first main face a first cambered face beingused for coupling at a junction of the first width edge and the firstside face, and a second cambered face being used for coupling at ajunction of the second width edge and the first side face, a shape ofthe second main face being a rectangle, the margin of the second mainface comprising a third width edge and a fourth width edge in a widthdirection of the second main face, a fifth cambered face being used forcoupling at a junction of the third width edge and the second side face,and a sixth cambered face being used for coupling at a junction of thefourth width edge and the second side face, the first cambered face andthe second cambered face being asymmetrical relative to a second crosssection located at a central position in a length direction of theterminal, and the fifth cambered face and the sixth cambered face beingasymmetrical relative to the second cross section located at the centralposition in the length direction of the terminal.
 2. The terminalhousing of claim 1, wherein the inner-side and outer-side faces of thefirst vertex angle cambered thee are separately in a shape of a camberline on each first through-thickness cross section.
 3. The terminalhousing of claim 1, wherein the inner-side and the outer-side faces ofthe first vertex angle cambered face are separately in a shape of acamber line on each second through-thickness cross section.
 4. Theterminal housing of claim 1, wherein the inner-side and the outer-sidefaces of the first vertex angle cambered face are separately in a shapeof a camber line on each cross section that passes through the at leastone first vertex angle in the through-thickness direction of the firstpanel.
 5. The terminal housing of claim 1, wherein the inner-side andthe outer-side faces of the first vertex angle cambered face areseparately in a shape of a camber line on each cross section of thefirst panel in a direction parallel to the first main face.
 6. Theterminal housing of claim 1, wherein the two margins of the first mainface located on the two sides of the at least one first vertex angle arestraight edges or cambered edges.
 7. The terminal housing of claim 1,wherein the two margins of the first main face coupled to the two sidesof the at least one first vertex angle and the first side face arecoupled at a junction of the two margins of the first main face and thefirst side face using a cambered face.
 8. The terminal housing of claim1, wherein the first side face is a cambered side face or a plate sideface.
 9. The terminal housing of claim 1, wherein the first side facesurrounds a periphery of the first main face and is coupled to a marginof the periphery of the first main face.
 10. The terminal housing ofclaim 1, wherein a thickness of the first panel or a thickness of thesecond panel is even, and inner-side and outer-side faces of the firstpanel or inner-side and outer-side faces of the second panel are of aconsistent shape.
 11. The terminal housing of claim 1, furthercomprising a middle frame, and the first panel and the second panel arerespectively assembled on two sides of the middle frame.
 12. Theterminal housing of claim 1, wherein the first panel and the secondpanel are symmetrical relative to a first cross section located at acentral position in a through-thickness direction of the terminal. 13.The terminal housing of claim 1, wherein a shape of an outer surface ofthe first main face is any one of an oblong, a trapezoid, a heart shape,a star shape, a regular hexagon, and a boat shape.
 14. The terminalhousing of claim 1, wherein a third cambered face is used for couplingat a junction of the first length edge and the first side face, a fourthcambered face being used for coupling at a junction of the second lengthedge and the first side face, and the third cambered face and the fourthcambered face being symmetrical relative to a third cross sectionlocated at a central position in a width direction of the terminal. 15.The terminal housing of claim 1, wherein the margin of the second mainface comprises a third length edge and a fourth length edge in a lengthdirection of the second main face, a seventh cambered face is used forcoupling at a junction of the third length edge and the second sideface, an eighth cambered face is used for coupling at a junction of thefourth length edge and the second side face, and the seventh camberedface and the eighth cambered face being symmetrical relative to a thirdcross section located at a central position in a width direction of theterminal.
 16. The terminal housing of claim 1, wherein the first panelor the second panel is a display screen.
 17. A terminal, comprising: aterminal housing; a circuit board disposed in the terminal housing; anda part disposed on the circuit board, the terminal housing comprising afirst panel and a second panel, the first panel and the second panelbeing respectively snap-fit on front and rear sides of a terminal, thefirst panel and the second panel being disposed opposite to each other,a material of the first panel or a material of the second panel beingglass, the first panel comprising a first main face that is flat andstraight, and a first side face coupled to a margin of the first mainface, the first main face comprising at least one first vertex angle,two margins on two sides of the at least one first vertex angle andcoupled to the at least one first vertex angle, and cross sections in athrough-thickness direction of the first panel and respectively verticalto the two margins coupled to the at least one first vertex angle arerespectively a first through-thickness cross section and a secondthrough-thickness cross section, a location of the at least one firstvertex angle of the first main face being coupled to the first side faceat a junction of the location of the at least one first vertex angle andthe first side face using a first vertex angle cambered face, inner-sideand outer-side faces of the at least one first vertex angle camberedface being separately in a shape of a camber line on the firstthrough-thickness cross section that passes through the at least onefirst vertex angle, the inner-side and the outer-side faces of the firstvertex angle cambered face being separately in a shape of a camber lineon the second through-thickness cross section that passes through the atleast one first vertex angle, the second panel comprising a second mainface that is fiat and straight, and a second side face coupled to amargin of the second main face, the second main face comprising at leastone second vertex angle, two margins on two sides of the at least onesecond vertex angle and coupled to the at least one second vertex angle,and cross sections in a through-thickness direction of the second panelrespectively vertical to the two margins coupled to the at least onesecond vertex angle being respectively a third through-thickness crosssection and a fourth through-thickness cross section, a location of theat least one second vertex angle of the second main face being coupledto the second side face at a junction of the location of the at leastone second vertex angle and the second side face using a second vertexangle cambered face, inner-side and outer-side faces of the secondvertex angle cambered face being separately in a shape of a camber lineon the third through-thickness cross section that passes through the atleast one second vertex angle, the inner-side and the outer-side facesof the at least one second vertex angle cambered face being separatelyin a shape of a camber line on the fourth through-thickness crosssection that passes through the at least one second vertex angle, ashape of the first main face being a rectangle, the margin of the firstmain face comprising a first width edge and a second width edge in awidth direction of the first main face, a first cambered face being usedfor coupling at a junction of the first width edge and the first sideface, and a second cambered face being used for coupling at a junctionof the second width edge and the first side face, a shape of the secondmain face being a rectangle, the margin, of the second main facecomprising a third width edge and a fourth width edge in a widthdirection of the second main face, a fifth cambered face being used forcoupling at a junction of the third width edge and the second side face,and a sixth cambered face being used for coupling at a junction of thefourth width edge and the second side face, the first cambered face andthe second cambered face being asymmetrical relative to a second crosssection located at a central position in a length direction of theterminal, and the fifth cambered face and the sixth cambered face beingasymmetrical relative to the second cross section located at the centralposition in the length direction of the terminal.